Optical seat occupation sensor network

ABSTRACT

The invention relates to a sensor arrangement for seat occupation detection, comprising a fiber-optic sensor network consisting of at least two sensors. The sensor network detest for example local damping modifications in a fiber network that are caused by microbends or modifications of the Bragg wavelength of fiber-optic Bragg grating sensors (FBGS) distributed in the fiber network that are ceased by loads. The optical sensor network is resistant to electromagnetic parasitic inductions. Due to the nature of the optical lass or polymer optical fibers it is for example possible to integrate the network into the textile cover of the seat or into a cushion.

BACKGROUND OF THE INVENTION

[0001] 1.Field of the Invention

[0002] The invention concerns a sensor network according to the precharacterizing portion of patent claim 1.

[0003] The present invention is concerned with the problem that, for the directed or proportionate activation of an airbag in a vehicle, it is of importance to have knowledge of the weight on the seat as well as the load distribution over the seat surface. The forcefulness of the airbag explosion should occur differentially based on the total weight of the occupants. If, in addition, the load distribution on the seat is known with high site-specificity, it also becomes possible therefrom to make a distinction between objects and persons on the seat.

[0004] 2.Description of the Related Art

[0005] For sensing seat occupancy it is known to use, for example, seat mats in which an electrical resistance network is integrated. The weight information is determined from the changes in resistance of the resistance network.

[0006] A disadvantage of this system is that it is prone to error due to electromagnetic interference, for example, due to electrostatic discharge. Besides this, neither the total weight determination nor the determination of the spatial weight distribution are sufficiently precise for purposes of controlling a complex airbag system.

SUMMARY OF THE INVENTION

[0007] It is the task of the present invention to provide a sensor network for determination of seat occupancy, with which a directed controllable actuation of an airbag system in a vehicle can occur.

[0008] The invention is described in claim 1. Advantageous embodiments and further developments are set forth in the dependent claims.

[0009] The invention has the advantage that an optical sensor network is employed that is resistant to electromagnetic interference.

[0010] It is further advantageous that during the occupancy of a seat by an object (for example a child seat) an airbag activation can be selectively prevented. If an adult person is on the seat, the weight distribution on the seat is used for determination of the position within the internal space and therewith used for directed or proportionate activation of a multi-airbag system.

BRIEF DESCRIPTION OF THE DRAWING

[0011] The invention is described by reference to illustrative embodiments with reference to schematic figures.

[0012]FIG. 1 shows an optical sensor network of micro-curvature sensors.

[0013]FIG. 2a, b, c show an optical sensor network with Bragg grating sensors or sensors which are responsive to a change in intensity.

BRIEF DESCRIPTION OF THE DRAWING

[0014] The invention is based on the presumption that a fiber-optic sensor network comprising at least two sensors is employed as the sensor system which is resistant to electromagnetic interference. As a result of the composition of the optical glass or polymer light guides it is possible to integrate the network in, for example, the textile cover of a seat or a pillow.

[0015] Sensors are used which detect or register, for example, local damping changes caused by microbends in a fiber network, or load-induced modifications of the Bragg wavelength of fiber-optic Bragg grating sensors (FBGS) distributed in the fiber network. The optical sensor network is impervious to electromagnetic parasitic inductions. If the sensor network is constructed of sensors of which the sensor effect is caused by damping effects, then a spatial resolution of the seat occupancy is possible by separate reading of the individual sensor branches. In FIG. 1 there is shown, for example, an optical sensor network of micro-curvature sensors S1 through SN. For each sensor one fiber line F leads to an individual detector in a detector plane E. The various sensor fiber lines are coupled to one or more light sources L.

[0016] In a further embodiment the spatial resolution for, for example, an fiber-optic Bragg grating sensor network according to FIG. 2a, b, occurs by the cascading of for example differing Bragg grating sensors FBGS with varying Bragg wavelengths. The cascading of the sensors reduces the number of the necessary detectors E. The coupling-in of light occurs via a light source L.

[0017] The Bragg grating sensors are either operated in reflection mode (FIG. 2a) or in transmission (FIG. 2b) mode.

[0018] In the case of sensors operating based on cascading, which react for example to local damping changes (intensity changes) (FIG. 2c), the spatial resolution of the seat occupancy occurs by a locally resolved damping measurement processes (OTDR). The light is coupled-in via a light source L.

[0019] The cascading arrangement of the sensors facilitates the construction of a more widely distributed, complex sensor network. 

1-9. (cancelled)
 10. A sensor arrangement for detecting seat occupancy, comprising at least one optical sensor, wherein at least two optical sensors are positioned at various locations on the seat surface, and wherein an analysis of seat load distribution can be made on the basis of changes in sensor signals.
 11. A sensor arrangement according to claim 10, wherein a fiber-optic sensor network is integrated in the seat.
 12. A sensor arrangement according to claim 10, wherein the sensors detect micro-curvatures and changes in damping caused thereby.
 13. A sensor arrangement according to claim 10, wherein the sensors are Bragg grating sensors, which are operated either in reflection or transmission mode.
 14. A sensor arrangement according to claim 10, wherein the optical sensor network is comprised of sensors S1 through SN, wherein for each sensor a fiber line F leads to an individual detector in a detector plane E, wherein light from one or more light sources L is coupled in to the various sensor fiber lines, and wherein a classifying or reading-out unit resolves the spatial distribution of the seat occupancy by separately reading-out the individual sensor branches.
 15. A sensor arrangement according to claim 10, wherein the sensors are arranged in a cascade arrangement and wherein the spatial resolution of the seat occupancy occurs by the cascading of individual sensors.
 16. A sensor arrangement according to claim 10, wherein the sensor network is woven into the cover of the seat.
 17. A sensor arrangement according to claim 10, wherein the sensor network is integrated in a seat pillow.
 18. A sensor arrangement according to claim 10, wherein the load distribution enables a determination of the position of a person seated on the seat. 